蛋白质-蛋白质相互作用和溶剂粘度对拥挤环境中蛋白质旋转扩散的影响。
Effect of protein-protein interactions and solvent viscosity on the rotational diffusion of proteins in crowded environments.
机构信息
Department of Biochemistry and Molecular Biology, Michigan State University, 603 Wilson Rd., Room 218 BCH, East Lansing, MI 48824, USA.
出版信息
Phys Chem Chem Phys. 2019 Jan 2;21(2):876-883. doi: 10.1039/c8cp06142d.
Abstract
The rotational diffusion of a protein in the presence of protein crowder molecules was analyzed via computer simulations. Cluster formation as a result of transient intermolecular contacts was identified as the dominant effect for reduced rotational diffusion upon crowding. The slow-down in diffusion was primarily correlated with direct protein-protein contacts rather than indirect interactions via shared hydration layers. But increased solvent viscosity due to crowding contributed to a lesser extent. Key protein-protein contacts correlated with a slow-down in diffusion involve largely interactions between charged and polar groups suggesting that the surface composition of a given protein and the resulting propensity for forming interactions with surrounding proteins in a crowded cellular environment may be the major determinant of its diffusive properties.
摘要
通过计算机模拟分析了蛋白质在蛋白质拥挤分子存在下的旋转扩散。发现由于瞬时分子间接触而导致的聚集体形成是拥挤导致旋转扩散减少的主要效应。扩散的减缓主要与直接的蛋白质-蛋白质接触相关,而不是通过共享水合层的间接相互作用。但是由于拥挤导致的溶剂粘度增加的贡献较小。与扩散减缓相关的关键蛋白质-蛋白质接触主要涉及带电和极性基团之间的相互作用,这表明给定蛋白质的表面组成及其在拥挤的细胞环境中与周围蛋白质形成相互作用的倾向可能是其扩散性质的主要决定因素。
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